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The Journal of Neuroscience, September 7, 2005, 25(36):8240-8249; doi:10.1523/JNEUROSCI.1808-05.2005

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Neurobiology of Disease
Microglial Phagocytosis Induced by Fibrillar -Amyloid and IgGs Are Differentially Regulated by Proinflammatory Cytokines

Jessica Koenigsknecht-Talboo and Gary E. Landreth

Alzheimer Research Laboratory, Department of Neurosciences, Case Western Reserve University School of Medicine, Cleveland, Ohio 44106

	Abstract

Top Abstract Introduction Materials and Methods Results Discussion References

 
Microglia undergo a phenotypic activation in response to fibrillar -amyloid (fA) deposition in the brains of Alzheimer's disease (AD) patients, resulting in their elaboration of inflammatory molecules. Despite the presence of abundant plaque-associated microglia in the brains of AD patients and in animal models of the disease, microglia fail to efficiently clear fA deposits. However, they can be induced to do so during A vaccination therapy attributable to anti-A antibody stimulation of IgG receptor (FcR)-mediated phagocytic clearance of A plaques.

We report that proinflammatory cytokines attenuate microglial phagocytosis stimulated by fA or complement receptor 3 and argue that this may, in part, underlie the accumulation of fA-containing plaques within the AD brain. The proinflammatory suppression of fA-elicited phagocytosis is dependent on nuclear factor B activation. Significantly, the proinflammatory cytokines do not inhibit phagocytosis elicited by antibody-mediated activation of FcR, which may contribute to the efficiency of A vaccination-based therapy. Importantly, the proinflammatory suppression of fA phagocytosis can be relieved by the coincubation with anti-inflammatory cytokines, cyclooxygenase inhibitors, ibuprofen, or an E prostanoid receptor antagonist, suggesting that proinflammatory cytokines induce the production of prostaglandins, leading to an E prostanoid receptor-dependent inhibition of phagocytosis. These findings support anti-inflammatory therapies for the treatment of AD.

Key words: phagocytosis; -amyloid; Alzheimer's disease; NSAIDs; inflammation; cytokines

	Introduction

Top Abstract Introduction Materials and Methods Results Discussion References

 
The Alzheimer's disease (AD) brain is characterized by the presence of senile plaques, invariantly surrounded by abundant activated microglia. One of the central enigmas in AD is why microglia, despite their "activated" state, fail to effectively mount a phagocytic response to ingest and degrade the insoluble fibrillar -amyloid (fA) deposits. Vaccination studies have demonstrated that phagocytic removal of amyloid plaques can result from the addition of antibodies to A directly to the brain (Bacskai et al., 2002) or after immunization in animal models of AD (Schenk et al., 1999; Bard et al., 2000; Wilcock et al., 2003). Similarly, it has been argued that this mechanism may be responsible for reduction of plaque burden in humans immunized with fA. These studies argue that plaque removal results from stimulation of microglial phagocytosis during engagement of IgG (FcR) receptors by anti-A antibodies bound to the plaques (Schenk et al., 1999; Bard et al., 2000; Wilcock et al., 2003, 2004), although other mechanisms may act in parallel (Wilcock et al., 2003, 2004; Wyss-Coray et al., 2003; Koistinaho et al., 2004).

Microglia interact with fA through an ensemble of cell surface receptors (Bamberger et al., 2003), leading to the activation of signal transduction pathways that result in phenotypic activation of these cells (Combs et al., 1999, 2001). The secretion of cytokines, chemokines, and a diverse array of other proinflammatory molecules, including prostaglandins (PGs), accompany microglial activation. Indeed, the AD brain and animal models of the disease exhibit elevated levels of these molecules (Akiyama et al., 2000). This chronic proinflammatory environment is postulated to contribute to the cognitive deficits and neuronal loss that characterize the disease (Akiyama et al., 2000).

Microglia are typically characterized as "quiescent" or "activated," and it has only recently been appreciated that these cells exhibit an array of phenotypes, governed by their local environment (Goerdt and Orfanos, 1999; Gordon, 2003). Cells exhibiting these nonclassical phenotypes have recently been termed "alternatively activated" (Goerdt and Orfanos, 1999; Mantovani et al., 2002; Duffield, 2003; Gordon, 2003). Microglia may display an activated proinflammatory phenotype yet be unable to initiate a phagocytic response. We have shown recently that microglia respond to fA by stimulation of a robust 1-integrin-dependent phagocytic process (Koenigsknecht and Landreth, 2004). We now question why this response is not evident in the AD brain.

We report that proinflammatory cytokines inhibit phagocytosis elicited by engagement of the A receptor complex and complement receptor 3 (CR3). This effect may cause the accumulation of amyloid plaques within the AD brain by suppression of endogenous fA peptide clearance mechanisms. Importantly, antibody-stimulated phagocytosis mediated through FcR was unaffected by proinflammatory cytokines and argue that this effect may underlie the efficacy of vaccination-based therapies in reducing A plaque burden. We also report that incubation of cells with anti-inflammatory cytokines or cyclooxygenase (COX) inhibitors, including ibuprofen, blocks the ability of proinflammatory cytokines to suppress fA-elicited phagocytosis through the inhibition of prostaglandin E2 (PGE2) production or its signaling pathways. These findings support the use of anti-inflammatory therapies in the treatment of AD.

	Materials and Methods

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Materials. A_25–35 and A_1–42 were purchased from American Peptide Company (Sunnyvale, CA). A peptides corresponding to amino acids 25–35 and 1–42 were dissolved in sterile water and incubated for 5 d at 37°C to allow for fibrilization (Burdick et al., 1992; Lorenzo and Yankner, 1994; Terzi et al., 1994). We cannot rule out that the A_1–42 preparation may contain some oligomers. Zymosan was purchased from Sigma (St. Louis, MO) and was opsonized with complement by incubating with mouse serum for 30 min at 37°C, followed by 10 washes with 0.85% NaCl before resuspension in PBS. Immune IgG was prepared from goat anti-rabbit IgG from Sigma and rabbit anti-mouse IgG from Cappel (Aurora, OH) in a 5:1 ratio. Parthenolide, butaprost, and AH6809 were also purchased from Sigma. Interleukin-4 (IL-4) and IL-10 were purchased from Biosource (Camarillo, CA). IL-13, interferon (IFN), IL-1, tumor necrosis factor (TNF), and monocyte chemoattractant protein (MCP-1) were from R & D Systems (Minneapolis, MN). CD40L was purchased from Alexis (San Diego, CA). Nile red fluorospheres (1 µm microspheres) and AlexaFluor 488-phalloidin were purchased from Molecular Probes (Eugene, OR). TGF was purchased from Promega (Madison, WI), lipopolysaccharide (LPS) was from List Biologic (Campbell, CA), SN50 and SN50M were from Biomol (Plymouth Meeting, PA), and CAY10404 [GenBank] and SC-560 were from Cayman Chemicals (Ann Arbor, MI).

Tissue culture. The immortalized murine microglia cell line BV-2 (Blasi et al., 1990) was grown and maintained in DMEM containing 2% fetal bovine serum and gentamycin in 5% CO₂. BV-2 cells used in these experiments were between passage numbers 20 and 40. No differences in results were observed between different passage numbers. Primary microglia were derived from postnatal 1–2 d mouse brains (C57BL/6J) as described previously (McDonald et al., 1997).

Phagocytosis assay. Phagocytosis was assayed as described previously (Koenigsknecht and Landreth, 2004). Briefly, BV-2 cells were collected, and 1 x 10⁶ cells were plated in serum-free medium in 35 mm plates and then incubated in the presence or absence of proinflammatory or anti-inflammatory cytokines overnight. The cells were then treated for 30 min in the absence or presence of 60 µM (63.6 µg/ml) fA_25–35 peptide, 5 µM (22.6 µg/ml) fA_1–42 peptide, 1 mg/ml complement-opsonized zymosan, or 1 mg/ml immune IgG. Fluorescent microspheres were washed in PBS containing 1 mg/ml BSA and then added to the cells for 30 min. The fluorescent microspheres were used as a marker of fluid phase phagocytosis. Cells were then fixed with 2% paraformaldehyde, and three random fields of cells (>100 cells) were counted on an inverted fluorescent microscope.

Phalloidin staining. BV-2 cells were collected and then plated on coverslips (150,000 BV-2 cells per coverslip) resting in a 24-well plate overnight in serum-free medium in the presence or absence of cytokines. The cells were then incubated in the absence or presence of 60 µM (63.6 µg/ml) fA_25–35 peptide for 30 min. The cells were rinsed with PBS before being fixed in 3.6% paraformaldehyde and washed again in PBS. The cells were then incubated at room temperature with 0.1% Triton X-100 buffer for 5 min and washed again in PBS. Finally, AlexaFluor 488-phalloidin (1.6 U diluted in PBS) was added to the coverslips and incubated at room temperature protected from light for 25 min. The coverslips were mounted on glass slides.

	Results

Top Abstract Introduction Materials and Methods Results Discussion References

 
Proinflammatory cytokines inhibit fA and opsonized zymosan-stimulated phagocytosis but do not inhibit immune IgG-mediated phagocytosis
We established a phagocytosis assay that measures ligand-stimulated phagocytosis through the bulk phase uptake of fluorescent microspheres to examine the phagocytic response in microglia (Koenigsknecht and Landreth, 2004). BV-2 microglial cells were used because they have been proven to faithfully mimic behaviors of primary microglial cells (Bocchini et al., 1992) as well as exhibit a robust phagocytic response (Kopec and Carroll, 1998; Koenigsknecht and Landreth, 2004). We wanted to test the hypothesis that a proinflammatory environment may act to suppress the capacity of microglia to mount a phagocytic response. We have shown previously that microglia exhibit both classical (types I and II) phagocytic responses to immune IgG stimulation of the FcR and complement-opsonized zymosan stimulation of CR3, respectively. However, microglia respond to fA through the fA receptor complex via a novel and mechanistically distinct 1-integrin-dependent phagocytic response (Koenigsknecht and Landreth, 2004). To test the effect of a proinflammatory environment on the various types of phagocytosis, BV-2 cells were treated with LPS for 6 h. LPS elicits the production of proinflammatory cytokines from microglia and macrophages (Zielasek and Hartung, 1996). Moreover, LPS treatment has been demonstrated to increase neuroinflammation and accelerate fA deposition in animal models of AD attributable to microglial cytokine production (Qiao et al., 2001). After LPS treatment, the cells were incubated with phagocytic-stimulating ligands, and phagocytosis was quantified. LPS incubation before stimulation of the cells with fA_1–42, fA_25–35, or mouse complement-opsonized zymosan suppressed phagocytosis, indicating that proinflammatory stimulation of microglia abrogates the capacity of the cells to mount a phagocytic response during stimulation of the fA receptor complex or CR3 (Fig. 1A). Remarkably, immune IgG-elicited phagocytosis was unaffected, demonstrating that the FcR still effectively functions to stimulate phagocytosis in the presence of inflammatory stimuli.

The observation that a difference in modulation of phagocytosis was shown among the three types of phagocytosis by LPS treatment led us to evaluate the effects of specific proinflammatory cytokines and chemokines. BV-2 cells were treated overnight with IL-1, TNF, IFN, MCP-1, and CD40L before stimulation with phagocytic ligands. MCP-1 is a microglial-derived chemokine found in the AD brain associated with senile plaques (Ishizuka et al., 1997). CD40 is a transmembrane receptor that binds CD40L (CD154), stimulating the production of proinflammatory cytokines, and has been postulated to participate in disease pathophysiology (Tan et al., 1999, 2002; Wesemann et al., 2002). Microglia express low amounts of CD40, but CD40 expression is upregulated after stimulation with proinflammatory stimuli. Microglia associated with senile plaques express increased levels of the proinflammatory cytokines, IL-1, and TNF (Hoozemans et al., 2001). Every proinflammatory agent tested in the phagocytosis assay demonstrated the same inhibition of fA and opsonized zymosan-stimulated phagocytosis but had no affect on immune IgG-mediated phagocytosis, identical to the effect observed in LPS-treated cells (Fig. 1B). These proinflammatory agents, acting alone, did not affect phagocytosis.

We next examined in detail the ability of IL-1 to suppress fA-elicited phagocytosis in BV-2 cells. A time course demonstrated that the cells required an exposure to IL-1 for 3 h or more before fA stimulation to attenuate fA-stimulated phagocytosis (Fig. 2A). Phagocytosis stimulated by fA was not affected by the presence of IL-1 for 1 h or less, suggesting that proinflammatory inhibition of fA-stimulated phagocytosis might be transcriptionally regulated.

We further evaluated a role for transcriptional regulation in IL-1-inhibited fA-stimulated phagocytosis. Inhibitors of nuclear factor B (NFB) activation were used. NFB has been proven to play an essential role in the regulation of inflammation (Baldwin, 1996; Combs et al., 2001; Tak and Firestein, 2001). Parthenolide specifically targets the inhibitor of B kinase and therefore inhibits NFB activation (Hehner et al., 1999). Treatment of BV-2 cells with parthenolide for 3 h, followed by a 3 h incubation with IL-1, restored phagocytosis in fA-treated cells (Fig. 2B). To verify the involvement of NFB, we also used SN50 to inhibit NFB. SN50 has been shown to inhibit the translocation of NFB from the cytoplasm to the nucleus (Lin et al., 1995). SN50 also rescued phagocytosis elicited by fA in the presence of IL-1 (Fig. 2C). Furthermore, SN50M, an inactive form of SN50, did not restore phagocytosis of fA in a proinflammatory environment (Fig. 2C). From these data, we concluded that NFB-dependent transcription of proinflammatory genes was essential for the suppression of fA-elicited phagocytosis in a proinflammatory environment.

Anti-inflammatory cytokines do not directly stimulate or inhibit phagocytosis
We next examined the effect of anti-inflammatory cytokines on phagocytosis by overnight preincubation of BV-2 cells with IL-4, IL-10, IL-13, or TGF before stimulation of the cells with fA, opsonized zymosan, or immune IgG. These cytokines were tested for their effects on microglial phagocytosis because they have been shown to promote alternative activation of microglia (Goerdt and Orfanos, 1999; Mantovani et al., 2002; Duffield, 2003). The anti-inflammatory cytokines neither stimulated nor inhibited phagocytosis elicited by any of the phagocytic ligands (Fig. 3).

fA_1–42 elicits phagocytosis in primary microglia in an anti-inflammatory, but not a proinflammatory, milieu
Primary murine microglia were evaluated to determine whether proinflammatory environments could also regulate their capacity to stimulate phagocytosis. Microglia were treated with LPS for 6 h to induce a proinflammatory environment as was demonstrated previously with BV-2 cells. LPS treatment before stimulation with fA_1–42 suppressed phagocytosis in primary microglial cells (Fig. 4A). Specific proinflammatory and anti-inflammatory cytokines were also evaluated for their ability to regulate microglial phagocytosis. The proinflammatory cytokine IL-1 suppressed fA-mediated phagocytosis (Fig. 4B). However, the fA-stimulated phagocytic mechanism was unaffected by the presence of IL-4, an anti-inflammatory cytokine (Fig. 4B), and IL-4 had no affect when added alone. We concluded that proinflammatory cytokines regulated microglial phagocytosis in primary microglial cells in a similar manner as in BV-2 cells.

View larger version (27K): [in this window] [in a new window]   Figure 1. Proinflammatory cytokines inhibit fA and opsonized zymosan-stimulated phagocytosis but do not affect immune IgG phagocytosis. A, BV-2 cells were exposed to LPS (1µg/ml) for 6 h to produce a proinflammatory environment. The cells were then stimulated with fA (60 µM fA25–35 and 5 µM fA1–42), mouse complement-opsonized zymosan (mOZ; 1 mg/ml), and immune IgG (1 mg/ml) for 30 min, followed by 30 min of incubation with fluorescent microspheres. The fraction of phagocytically active cells was then determined. B, BV-2 cells were incubated with proinflammatory cytokines (15 ng/ml IL-1, 10 ng/ml TNF, and 100 ng/ml IFN), CD40L (1 µg/ml), or MCP-1 (20 ng/ml) overnight before stimulation with phagocytic-stimulating ligands for 30 min. Fluorescent microspheres were then added to the cells for 30 min. The fraction of phagocytically active cells was then determined. *p < 0.01, **p < 0.001, and #p < 0.05 compared with control. This experiment is representative of three independent experiments.

 
Proinflammatory and anti-inflammatory treated cells exhibit morphological differences
Treatment of microglia with fA elicits a 1-integrin dependent change in cellular morphology similar to that observed in a type I phagocytic response (Koenigsknecht and Landreth, 2004). We next asked whether the morphology of the phagocytically active cells was different between the anti-inflammatory and the proinflammatory cytokine-treated cells. BV-2 cells were treated in the presence or absence of cytokines overnight before fA stimulation. The cells were then stained with phalloidin to label cytoskeletal filamentous actin (F-actin). The cells treated with fA alone or in combination with IL-4 extended processes and contained phagocytosed microspheres (Fig. 5). In contrast, the cells that were treated with IL-1 before incubation with fA were similar to untreated cells, demonstrating that proinflammatory cytokines prevented cytoskeletal reorganization necessary for phagocytosis.

View larger version (19K): [in this window] [in a new window]   Figure 2. Proinflammatory cytokines inhibit fA-elicited phagocytosis by a transcriptionally dependent mechanism. A, BV-2 cells were incubated with IL-1 (15 ng/ml) for indicated time periods before fA25–35 (60 µM) stimulation for 30 min and the addition of fluorescent microspheres for 30 min. BV-2 cells were incubated with parthenolide (15µM)(B), SN50 (100µg/ml) (C), or SN50M (100 µg/ml) (C) for 3 h before stimulation with IL-1 (15 ng/ml) for 3 h. The cells were then incubated with fA25–35 (60µM) for 30 min, followed by the addition of fluorescent microspheres for 30 min. The fraction of phagocytically active cells was then determined. *p < 0.01 and **p < 0.001 compared with control. The data are representative of three independent experiments.

 
Anti-inflammatory cytokines restore phagocytic activity
It has been demonstrated that anti-inflammatory and proinflammatory cytokines exhibit antagonistic actions in macrophages (Hamilton et al., 1999; Duffield, 2003). We examined cells incubated simultaneously with anti-inflammatory and proinflammatory cytokines to determine whether anti-inflammatory cytokines could suppress the inhibitory actions of proinflammatory cytokines and restore phagocytosis in fA-treated cells. First, we incubated BV-2 cells with IL-1 (15 ng/ml) and IL-4 (5, 10, and 15 ng/ml) overnight before stimulation with fA. IL-4 treatments restored fA-elicited phagocytosis in a dose-dependent manner in the presence of IL-1 (Fig. 6A). We also demonstrated that IL-4 treatment prevented the ability of IFN to inhibit fA-mediated phagocytosis (Fig. 6B). Similarly, the LPS-mediated suppression of fA-stimulated phagocytosis was blocked by the action of the anti-inflammatory cytokine IL-10 (Fig. 6C). In each case, the anti-inflammatory cytokine restored phagocytosis in the presence of proinflammatory cytokines.

Ibuprofen rescues fA-elicited phagocytosis in a proinflammatory milieu
The observation that anti-inflammatory cytokines were able to restore fA-elicited phagocytosis in a proinflammatory environment led us to evaluate whether the nonsteroidal anti-inflammatory drug (NSAID) ibuprofen would elicit similar effects in a proinflammatory milieu. BV-2 cells were stimulated with IL-1 and racemic (R and S enantiomers) ibuprofen overnight before incubation with fA. Ibuprofen was able to restore phagocytosis stimulated by fA dose dependently in the presence of IL-1 (Fig. 7A).

We compared the ability of the two enantiomers of ibuprofen, S-ibuprofen and R-ibuprofen, to restore phagocytosis. The S-ibuprofen is the active enantiomer, whereas the R-enantiomer is inactive, with respect to COX inhibition. The S-ibuprofen was able to rescue phagocytosis in IL-1-treated cells, but R-ibuprofen was without effect (Fig. 7B). These data argue that COX activity may be involved in the suppression of phagocytosis by IL-1 and other proinflammatory cytokines.

To determine which of the two COX isoforms may play a role in the regulation of fA-stimulated phagocytosis, we used two specific COX inhibitors. SC-560 specifically inhibits COX-1 (Smith et al., 1998), whereas CAY10404 [GenBank] is a highly specific inhibitor of COX-2 (Parashar et al., 2005). COX-1 is constitutively expressed, whereas COX-2 expression is induced by inflammatory stimulation of microglia and macrophages (Vane et al., 1998; Akiyama et al., 2000). BV-2 cells were incubated with IL-1 overnight before a 1 h incubation with the COX inhibitors. Cells were then stimulated with fA, and the percentage of phagocytic cells was determined. The inhibition of COX-2 restored fA phagocytosis to a level similar to cells stimulated with only fA (Fig. 7C). The COX-1 inhibitor was unable to rescue phagocytosis driven by fA in a proinflammatory environment (Fig. 7C). We concluded from this experiment that COX-2 is involved in the suppression of fA-elicited phagocytosis in a proinflammatory environment.

Prostaglandin E2 suppresses fA-stimulated phagocytosis
The principal action of COX is to catalyze the synthesis of PGs from arachidonic acid. COX-2 is responsible for the production of PGE2. PGE2 binds and activates G-protein-coupled E prostanoid receptors (Narumiya et al., 1999) and has been shown to modulate phagocytosis of macrophages (Hutchison and Myers, 1987; Rossi et al., 1998; Aronoff et al., 2004). Shie et al. (2005) have shown recently that microglia in which the E prostanoid 2 (EP2) receptor gene was knocked out demonstrated increased phagocytosis of A compared with wild-type microglia. To determine whether PGE2 was involved in the suppression of fA-elicited phagocytosis in a proinflammatory milieu, we used the specific EP2 receptor agonist butaprost and an EP receptor antagonist, AH6809 (Aronoff et al., 2004; Pooler et al., 2004). Treatment of microglia with butaprost before fA stimulation inhibited fA-elicited phagocytosis, mimicking the effect that was seen in cells treated with IL-1 before stimulation with fA (Fig. 8A). Importantly, treatment with AH6809 after IL-1 incubation restored the ability of fA to elicit a phagocytic response (Fig. 8B). These data are consistent with a mechanism in which proinflammatory stimuli induce COX-2 expression and PGE2 production, which then likely signals through the EP2 receptor to inhibit fA-driven phagocytosis.

	Discussion

Top Abstract Introduction Materials and Methods Results Discussion References

 
We have reported previously the characterization of a microglial fA cell surface receptor complex (Bamberger et al., 2003) whose engagement leads to stimulation of phagocytosis (Koenigsknecht and Landreth, 2004). This receptor complex, whose principle constituents are CD36, CD47 (also termed integrin-associated protein), and the 61-integrin, recognizes and binds fA and elicits a novel phagocytic response that is reliant on the 1-integrin and is mechanistically distinct from classical type I or type II phagocytosis (Koenigsknecht and Landreth, 2004). It remains unclear why activated microglia that physically associate with amyloid plaques are unable to effectively phagocytose fA deposits in the AD brain or its animal models (Stalder et al., 2001).

View larger version (28K): [in this window] [in a new window]   Figure 3. Anti-inflammatory cytokines do not stimulate or inhibit phagocytosis. BV-2 cells were exposed to anti-inflammatory cytokines IL-4, IL-10, IL-13 (each at 10 ng/ml), or TGF (5 ng/ml) overnight before stimulation with fA (60 µM fA25–35 and 5 µM fA1–42), opsonized zymosan (mOZ; 1 mg/ml), or immune IgG (1 mg/ml) for 30 min. Fluorescent microspheres were then added to the cells for 30 min. The fraction of phagocytically active cells was then determined. **p < 0.001 compared with control. The experiment is representative of three independent experiments.

 

View larger version (14K): [in this window] [in a new window]   Figure 4. fA1–42 elicits phagocytosis in primary microglia in an anti-inflammatory, not a proinflammatory, milieu. A, Primary microglial cells were treated with LPS (1 µg/ml) for 6 h before stimulation with fA1–42 (5µM) for 30 min. Fluorescent microspheres were then added to the cells, and the fraction of phagocytically active cells was determined. B, Primary microglial cells were incubated overnight in the presence or absence of IL-1 (15ng/ml) or IL-4 (10ng/ml) before a 30 min treatment with fA1–42 (5µM). Fluorescent microspheres were then added to the cells. The fraction of phagocytically active cells was then determined. **p < 0.001 compared with control. The data are representative of three independent experiments.

 

View larger version (126K): [in this window] [in a new window]   Figure 5. Proinflammatory and anti-inflammatory treated cells exhibit morphological differences. BV-2 cells were treated with IL-1 (15 ng/ml) or IL-4 (10 ng/ml) overnight before stimulation with fA25–35 (60µM). Fluorescent microspheres were then added for 30 min. The cells were stained with phalloidin to visualize F-actin. Images of the cells were taken at 100x. Scale bar, 5 µm. This experiment is representative of three independent studies.

 
The mechanisms subserving the removal of fA from the brain are complex, and microglial phagocytosis is clearly only one of several mechanisms that operate in parallel to effect the elimination of the amyloid peptides and plaques from the brain. These include the phagocytic uptake of A through complement-mediated mechanisms (Wyss-Coray et al., 2002) and through the fA receptor complex (Koenigsknecht and Landreth, 2004), as well as trafficking of A into the peripheral circulation through apolipoprotein-mediated uptake by vasculature (Zlokovic, 2004). We postulated that chronic inflammation in the AD brain suppresses activation of phagocytic machinery and affects the ability of microglial cells to mount a phagocytic response, thereby inhibiting normal microglial clearance of fA and senile plaques. The brains of AD patients exhibit elevated levels of cytokines, chemokines, immune cell surface proteins, and complement proteins, which results in a feedforward process with a progressive upregulation of inflammation over the course of the disease (Akiyama et al., 2000). It has been demonstrated that inflammatory stimuli, such as CD40, upregulates expression of proinflammatory cytokines, as well as COX-2 and PGE2 levels (Tan et al., 1999, 2002; Inoue et al., 2004). There is clear evidence that microglia routinely survey the brain parenchyma (Nimmerjahn et al., 2005) and act normally through complement-dependent processes to remove A (Wyss-Coray et al., 2002) but are unable to prevent plaque formation in the AD brain. We found that microglia stimulated through the CR3 or the fA receptor complex are incapable of mounting a phagocytic response in the presence of proinflammatory cytokines, consistent with a very recent report by Townsend et al. (2005). Thus, inflammation inhibits both endogenous fA phagocytic mechanisms and reduces fA clearance and may explain, in part, the development and accumulation of senile plaques in the AD brain. The present study has demonstrated these effects in vitro with acute stimulation of phagocytes, and it remains possible that the chronic in vivo situation may be different.

View larger version (19K): [in this window] [in a new window]   Figure 6. Anti-inflammatory cytokines restore phagocytic activity. A, BV-2 cells were incubated with 15 ng/ml IL-1 and indicated doses of IL-4 overnight before a 30 min stimulation with 60 µM fA25–35, followed by incubation with fluorescent microspheres for 30 min. The fraction of phagocytically active cells was then determined. B, BV-2 cells were incubated with 10 ng/ml IL-4 and 100 ng/ml IFN overnight before a 30 min stimulation with 60µM fA25–35 and incubation with fluorescent microspheres for 30 min. The phagocytically active cells were then measured. C, BV-2 cells were incubated with 10 ng/ml IL-10 overnight beforea 6 h stimulation with 1µg/ml LPS. The cells were then stimulated with 60µM fA25–35 for 30 min and incubated with fluorescent microspheres for 30 min. The fraction of phagocytically active cells was then determined. **p < 0.001 compared with control. These data are representative of three independent experiments.

 
We demonstrated that proinflammatory cytokines act selectively to regulate different types of microglial phagocytosis, because these cytokines had no effect on immune IgG-elicited phagocytosis. The molecular basis for this effect is unknown but suggests that elements of the phagocyte machinery are not subject to inhibition by cAMP. Previous studies that characterized the classical types of microglial phagocytosis demonstrated that type I or FcR-mediated phagocytosis occurred in the presence of inflammation, whereas type II phagocytosis occurred in the absence of inflammatory signals (Caron and Hall, 1998). Importantly, we conclude from these experiments that microglial FcRs are able to maintain their ability to stimulate phagocytosis despite the chronic inflammatory environment found in the AD brain. This is significant because FcR-mediated phagocytosis of senile plaques induced by antibodies directed against fA are unaffected by the inflammatory status of the brain, and this effect may underlie the efficacy of A vaccination therapy in murine models of AD (Schenk et al., 1999; Bard et al., 2000; Wilcock et al., 2003, 2004).

The efficacy of A vaccination-based therapy in preventing amyloid deposition, removal of existing plaques, and behavioral improvement is well documented in animal models of AD (Morgan et al., 2000; Arendash et al., 2001; Jensen et al., 2005). Indeed, there is suggestive evidence of analogous effects in human clinical trials of A vaccination therapy (Hock et al., 2003; Orgogozo et al., 2003; Bayer et al., 2005). However, the mechanisms underlying the reduction of plaque burden are controversial. Wilcock et al. (2003, 2004) have elegantly demonstrated that attenuation of AD-like pathology in murine models of AD after A vaccination arises from both microglial phagocytosis and nonphagocytic mechanisms (A trafficking) that act in parallel. A peptide levels initially fall through microglia-independent mechanisms, whereas later reduction of A peptide levels and plaque burden is the result of phagocytic removal by microglia.

There is strong epidemiological evidence that long-term NSAID therapy has beneficial effects by reducing AD risk by 60–80% (McGeer et al., 1996; Stewart et al., 1997; in t'Veld et al., 2001), delaying onset, reducing the severity, and slowing the progression of AD (Rogers et al., 1993; Rich et al., 1995). Importantly, NSAID treatment is associated with a reduced number of plaque-associated microglia in the AD brain (Mackenzie and Munoz, 2001). The effect of proinflammatory stimulation of microglia is the rapid induction of COX-2 expression and the subsequent production of PGs (Akiyama et al., 2000). Indeed, COX-2 protein levels have been shown to be elevated in AD brains (Pasinetti and Aisen, 1998; Ho et al., 1999; Kitamura et al., 1999). The effect of anti-inflammatory cytokines is to suppress the NFB-dependent stimulation of COX-2 expression and PGE2 production in CD40-stimulated monocytes (Inoue et al., 2004), and we argue that this effect underlies the antagonist actions of these anti-inflammatory cytokines in restoring phagocytic activity in the presence of inflammatory stimuli. TGF overexpression in an animal model of AD resulted in a dramatic reduction in A plaque burden that was associated with microglial activation and enhanced phagocytosis (Wyss-Coray et al., 2001).

View larger version (26K): [in this window] [in a new window]   Figure 7. Ibuprofen rescues fA-elicited phagocytosis in a proinflammatory milieu. A, BV-2 cells were treated with racemic ibuprofen at indicated doses and IL-1 (15 ng/ml) overnight before stimulation with fA25–35 (60µM) for 30 min, followed by a 30 min incubation with fluorescent microspheres. The fraction of phagocytically active cells was then determined. B, BV-2 cells were treated with racemic ibuprofen, S-ibuprofen, or R-ibuprofen at indicated doses together with IL-1 (15 ng/ml) overnight. Cells were then stimulated with fA25–35 (60 µM) for 30 min before incubation with fluorescent microspheres for 30 min. The phagocytically active cells were then measured. C, BV-2 cells were treated with IL-1 (15 ng/ml) overnight beforea 1 h incubation with CAY10404 [GenBank] , a COX-2 inhibitor, at indicated doses or SC-560, a COX-1 inhibitor, at indicated doses. Cells were then stimulated with fA25–35 (60µM) for 30 min before the addition of fluorescent microspheres for 30 min. The fraction of phagocytically active cells was then determined. *p < 0.01, **p < 0.001, and #p < 0.05 compared with control. These data are representative of three independent experiments.

 

View larger version (20K): [in this window] [in a new window]   Figure 8. Prostaglandin E2 regulates the suppression of fA-stimulated phagocytosis in a proinflammatory milieu. A, BV-2 cells were treated with IL-1 (15 ng/ml) overnight before the addition of butaprost, an EP2 receptor agonist, at indicated doses for 1 h before stimulation with fA25–35 (60 µM) for 30 min. Cells were then incubated with fluorescent microspheres for 30 min. The percentage of phagocytically active cells was then determined. B, BV-2 cells were treated with IL-1 (15 ng/ml) overnight before the addition of AH6809, an EP receptor antagonist, at indicated doses for 1 h. Cells were then stimulated with fA25–35 (60 µM) for 30 min, followed by a 30 min incubation with fluorescent microspheres. The percentage of phagocytically active cells was then determined. *p < 0.01 and **p < 0.001 compared with control. These data are representative of three independent experiments.

 
The primary effect of NSAID action is the inhibition of COXs and the subsequent suppression of PG synthesis (Vane and Botting, 1998). We provide data that ibuprofen acts via this mechanism to counteract the ability of proinflammatory cytokines to inhibit phagocytosis elicited by engagement of the fA receptor complex. Ibuprofen has been implicated in the prevention and treatment of AD. Treatment of AD murine models with ibuprofen resulted in a reduction of plaque burden and A peptide levels that was not observed in untreated mice (Lim et al., 2000; Jantzen et al., 2002; Yan et al., 2003). Ibuprofen-treated animals exhibited a reduction in the number of reactive microglia and their proinflammatory products, as well as improved behavior (Lim et al., 2000). We demonstrated that anti-inflammatory cytokines and ibuprofen were able to restore fA-elicited phagocytosis in a proinflammatory milieu. This rescue effect was mediated by the inhibition of COX-2, reducing PGE2 levels, and signaling through the EP2 receptor. Importantly, this conclusion was validated by a recent report by Shie et al. (2005). Our results also define a mechanism that may explain, in part, the animal data in which administration of ibuprofen results in a reduction of fA plaques. Our finding that ibuprofen acts to antagonize the action of inflammatory stimuli and restore phagocytosis provides a new mechanism whereby NSAIDs act to reduce AD risk.

There has been considerable controversy over the efficacy of anti-inflammatory therapies in reducing AD risk, as well as in the treatment of patients with the disease. The epidemiological studies have led to clinical trials of steroids (Aisen et al., 2000), COX-2-specific inhibitors, and naproxen in patient populations with mild to moderate AD (Aisen et al., 2003). These trials failed to demonstrate a salutary effect on AD progression. This outcome likely reflects the requirement for drug intervention at earlier stages of the disease because the epidemiological studies revealed that only long-term (at least 2 years) drug treatment provided the protection against AD (Stewart et al., 1997; in t'Veld et al., 2001), suggesting that these agents cannot functionally intervene in the disease process after it has become clinically evident. From a mechanistic prospective, the action of NSAIDs relative to disease pathophysiology has generated substantial controversy with the newly recognized ability of a subset of these drugs, including ibuprofen, to have anti-inflammatory actions through peroxisome proliferator-activated receptor activation (Lehmann et al., 1997; Jiang et al., 1998; Ricote et al., 1998; Combs et al., 2000) and to act on neurons to alter the specificity of amyloid precursor protein processing by directly effecting -secretase specificity, although the effects are only observed at high drug concentrations (Weggen et al., 2001; Sagi et al., 2003; Kukar et al., 2005). The effects observed in the present study were elicited at ibuprofen concentrations consistent with its action on COX and not through alternate mechanisms (Tegeder et al., 2001).

In summary, the present study supports the use of anti-inflammatory therapies in patient populations at risk for AD. Specifically, we have shown that ibuprofen, acting at therapeutically relevant concentrations on its canonical targets, the COXs, facilitate the normal clearance of fA by phagocytosis. Moreover, the action of anti-inflammatory cytokines in facilitating the clearance of fA validate this therapeutic approach. The present data also illustrate the phenotypic complexity of "reactive microglia" and argue that it may be possible to selectively target specific actions of these cells. These findings also have direct therapeutic relevance to AD through the recognition that vaccination-based removal of fA from the AD brain is unaffected by its inflammatory status.

	Footnotes

 
Received May 5, 2005; revised July 21, 2005; accepted July 21, 2005.

This work was supported by National Institutes of Health Grant AG20202 and by the Blanchette Hooker Rockefeller Foundation.

Correspondence should be addressed to Gary E. Landreth, Alzheimer Research Laboratory, E504, Case Western Reserve University School of Medicine, 10900 Euclid Avenue, Cleveland, OH 44106. E-mail:gel2{at}cwru.edu.

DOI:10.1523/JNEUROSCI.1808-05.2005

Copyright © 2005 Society for Neuroscience 0270-6474/05/258240-10$15.00/0

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